Patient specific reconstructive glenoid systems and methods

ABSTRACT

A system for repairing a glenoid defect of a specific patient can include a patient-specific punch and a patient-specific shaping block. The patient-specific punch can form a patient-specific glenoid implant from a bone puck. The patient-specific shaping block can shape the patient-specific glenoid implant to match and fill a glenoid defect of a specific patient.

PRIORITY APPLICATIONS

This application claims the benefit of priority to U.S. ProvisionalPatent Application Ser. No. 62/478,733, filed Mar. 30, 2017, the contentof which is hereby incorporated by reference in its entirety.

BACKGROUND

In some shoulder surgeries, the glenoid bone is used to anchor one ormore fasteners. Sometimes a patient's glenoid has one or more defectsthat can reduce the available screw purchase at the glenoid. Somecurrent practices for addressing a glenoid defect can involve lengthyprocesses, difficult procedures, removing too much of the glenoid,compromising the glenoid vault, or the like. Further, some currentpractices do not effectively correct the defect, are unable to address adefect interior to the peripheral edge of the glenoid, can create anirregular geometry within the shoulder joint, or the like.

Overview

To better illustrate the instrument disclosed herein, a non-limitinglist of examples is provided here:

In Example 1, a system can be provided for repairing a glenoid defect ofa specific patient, the system can include an impactor body, and apatient-specific punch coupled to the impactor body, thepatient-specific punch including a patient-specific void correspondingto the glenoid defect, is optionally configured such that the impactorbody is configured to drive the patient-specific punch into an implantmaterial to form a patient-specific glenoid implant.

In Example 2, the system of Example 1 is optionally configured such thatthe patient-specific punch can be removably coupled to the impactorbody.

In Example 3, the system of Example 1 or 2 is optionally configured suchthat the implant material can include a bone puck formed from a resectedportion of a humeral head.

In Example 4, they system of any of Examples 1-3 is optionallyconfigured such that the patient-specific glenoid implant can beconfigured to be coupled to a base plate that is configured to becoupled to the glenoid.

In Example 5, the system of Example 4 can optionally include apatient-specific shaping block configured to receive thepatient-specific glenoid implant in a shaping void, and a spacerconfigured for placement in the patient-specific shaping block, thespacer having a geometry corresponding to the base plate, the system isoptionally configured such that the shaping void is configured to matchthe glenoid defect, the system is optionally configured such that thepatient-specific glenoid implant is configured to be impacted such thatthe shaping void and the spacer shape the patient-specific glenoidimplant to repair the glenoid defect.

In Example 6, the system of Example 5 can optionally include an impactorhead configured to be removably coupled to the impactor body.

In Example 7, the system of Example 5 or 6 is optionally configured suchthat the patient-specific shaping block can further include a cover, thecover configured to receive a guide pin.

In Example 8, the system of any of Examples 5-7 can optionally include abase plate reamer configured to ream the patient-specific glenoidimplant to match features of the base plate.

In Example 9, the system of any of Examples 1-8 is optionally configuredsuch that the patient-specific punch can include knifed edges.

In Example 10, a system can be provided for repairing a glenoid defectof a specific patient, the system can include a patient-specific punchincluding a patient-specific void corresponding to the glenoid defect,the patient-specific punch configured to form a patient-specific glenoidimplant, and a patient-specific shaping block configured to receive thepatient-specific glenoid implant in a shaping void that matches theglenoid defect, the system is optionally configured such that thepatient-specific glenoid implant is configured to be impacted such thatthe shaping void shapes the patient-specific glenoid implant to fill theglenoid defect.

In Example 11, the system of Example 10 can optionally include a baseplate configured to be coupled to the patient-specific glenoid implantfor implantation in the specific patient.

In Example 12, the system of Example 11 can optionally include a spacerconfigured to be inserted into the patient-specific shaping block, thespacer having a geometry corresponding to the base plate.

In Example 13, the system of any of Examples 10-12 can optionallyinclude a bone cutter configured to form a bone puck, is optionallyconfigured such that the patient-specific punch is configured to impactthe bone puck to form the patient-specific glenoid implant.

In Example 14, the system of Example 13 is optionally configured suchthat the bone cutter can optionally include an extraction blockconfigured to receive a humeral head resection, a fastener configured toextend through the humeral head resection, and a rotatable bladeassembly configured to be received by, and rotate around, the fastenerto cut the humeral head resection to form the bone puck.

In Example 15, the system of any of Examples 10-14 can optionallyinclude an impactor body can include an attachment portion configured tobe removably coupled to one or more attachments, the system isoptionally configured such that the patient-specific punch is configuredto be removably coupled to the attachment portion of the impactor body.

In Example 16, the system of Example 15 can optionally include animpactor head attachment configured to be removably coupled to theattachment portion of the impactor body.

In Example 17, a method can be provided for repairing a glenoid defectof a specific patient, the method can include driving a patient-specificpunch into an implant material to create a patient-specific glenoidimplant, the method is optionally configured such that thepatient-specific punch can include a patient-specific void correspondingto the glenoid defect, placing the patient-specific glenoid implant in apatient-specific shaping block including a shaping void that matches theglenoid defect, and impacting the patient-specific glenoid implant, suchthat the patient-specific shaping block shapes the patient-specificimplant to fill the glenoid defect.

In Example 18, the method of Example 17 can optionally include formingthe bone puck from a resected portion of a humeral head.

In Example 19, the method of Example 17 or Example 18 can optionallyinclude reaming the patient-specific implant to accommodate a baseplate.

In Example 20, the method of Example 19 can optionally include couplingthe patient-specific glenoid implant to the base plate that isconfigured to be coupled to the glenoid.

In Example 21, the system or method of any of Examples 1-20 canoptionally be combined.

These and other examples and features of the present devices, systems,and methods will be set forth in part in the following DetailedDescription. This overview is intended to provide a summary of subjectmatter of the present patent application. It is not intended to providean exclusive or exhaustive removal of the invention. The detaileddescription is included to provide further information about the presentpatent application.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings, which are not necessarily drawn to scale, like numeralsmay describe similar components in different views. Like numerals havingdifferent letter suffixes may represent different instances of similarcomponents. The drawings illustrate generally, by way of example, butnot by way of limitation, various embodiments discussed in the presentdocument.

FIG. 1 is a perspective view of a patient-specific punch for forming apatient-specific glenoid implant corresponding to a glenoid defect of aspecific patient, in accordance with at least one example of the presentdisclosure.

FIG. 2A is a perspective view of a patient-specific shaping block forshaping the patient-specific glenoid implant, in accordance with atleast one example of the present disclosure.

FIG. 2B is another perspective view of the patient-specific shapingblock of FIG. 2A, in accordance with at least one example of the presentdisclosure.

FIG. 2C is a perspective view of a spacer and a spacer removal tool, inaccordance with at least one example of the present disclosure.

FIG. 2D is a cross-section view of a spacer inserted into apatient-specific shaping block to shape a patient-specific glenoidimplant, in accordance with at least one example of the presentdisclosure.

FIG. 3A is a perspective view of an impactor body and a patient-specificpunch attachment, in accordance with at least one example of the presentdisclosure.

FIG. 3B is a perspective view of an impactor head attachment for theimpactor body of FIG. 3A, in accordance with at least one example of thepresent disclosure.

FIG. 4 is a perspective view of a bone cutter, in accordance with atleast one example of the present disclosure.

FIG. 5 is a perspective view of a patient-specific bone substituteinjector, in accordance with at least one example of the presentdisclosure.

FIG. 6 is a perspective view of an injector and a patient-specific mold,in accordance with at least one example of the present disclosure.

FIG. 7 is a perspective view of a patient-specific glenoid implantimplanted in a corresponding glenoid defect of the specific patient, inaccordance with at least one example of the present disclosure.

DETAILED DESCRIPTION

In some shoulder surgeries, defects in a patient's glenoid can affectthe repair of the shoulder, since the glenoid can be used to anchorfasteners. These glenoid defects reduce the amount of available screwpurchase between the base plate and the cortical or cancellous bone ofthe patient. Some current procedures attempt to counteract the effect ofglenoid defects with bone substitutes and the use of cancellous bonefragments, but these processes are lengthy, difficult to place, and thebone fragments do not always fit the geometry of the glenoid defect'svoid since they are not patient-specific.

Current surgical options are limited for addressing a glenoid that hasexperienced a large magnitude of retroversion on the posterior rim ofthe glenoid (e.g., B2 Walch classification glenoid defects). Suchdefects allow the shoulder to be prone to subluxation through theposterior wall and could cause impingement within the muscular skeletalsystem. These defects come in a range of sizes and complex shapes, whichleave little to no bone along the posterior rim of glenoid and canspread anteriorly.

One current technique involves reaming the face of the glenoid down thelateral surface to eliminate the existing retroversion, created by wearbetween the glenoid and humerus. Another current technique utilizes anaugmented glenoid. Both of these current techniques involve taking asubstantial amount of bone from the glenoid. The glenoid vault only hasa certain amount of suitable bone before the vault is completelycompromised. Some current techniques only address defects of theperipheral edge of the glenoid. Many of these techniques can createirregular geometry within the shoulder joint.

The present disclosure provides various systems and methods related to apatient-specific glenoid implant for filling the void of a glenoiddefect of a specific patient. In at least one example, the presentdisclosure provides systems and methods for reconstructing the glenoidvault naturally utilizing autograft, allograft, bone substitute, or acombination of these. In at least one example, the resulting glenoidimplant will be patient-matched and fixated to existing bone as the newbone grows. In at least one example, the systems and methods of thepresent disclosure allow a surgeon to match a specific glenoid voidwhile reconstructing the glenoid rim and creating correct muscletensioning. Further, in at least one example the systems and methods ofthe present disclosure allow for preoperative planning and preparationto reduce surgical time. In at least one example, the systems andmethods of the present disclosure allow a surgeon to mitigate the riskof biocompatibility rejections, since the patient's body will be moreaccepting of an implant made from the patient's anatomy. While thepresent disclosure is described with reference to a glenoid repair, thesystems and methods of the present disclosure could also be used for anybone defect repair.

For the purposes of this disclosure, patient-specific can be defined asincluding dimensions specific to an individual patient, such that thedimensions would differ from patient to patient. That is, apatient-specific glenoid implant can be custom to an individualpatient's anatomy. In at least one example, patient-specific can bedefined as comprising a geometry that matches the anatomy of thespecific patient. In at least one example, patient-specific can bedefined as comprising a geometry that mirrors the anatomy of a specificpatient. In at least one example, patient-specific can be defined ascomprising a geometry that exactly matches the geometry of a specificpatient's anatomy. In at least one example, patient-specific can bedefined as having a geometry that completely fills a void in a specificpatient's anatomy. Patient-specific glenoid implants can allow for amore precise and successful repair of a glenoid defect.

FIG. 1 is a perspective view of a patient-specific punch 100 for forminga patient-specific glenoid implant 102 corresponding to a glenoid defect104 of a specific patient 106, in accordance with at least one exampleof the present disclosure. The glenoid defect 104 can have any geometryand be located anywhere on the glenoid 108 of the patient 106. Further,in at least one example, the patient 106 can have multiple glenoiddefects, and each glenoid defect can be repaired separately withmultiple patient-specific punches, or a single patient-specific punchcan be created to address multiple glenoid defects.

The patient-specific punch 100 can include a patient-specific void 110corresponding to the glenoid defect 104. In at least one example, thepatient-specific void 110 can be defined by knifed or cutting edges. Insome examples, the patient-specific void 110 can include a measuredgeometry of the glenoid defect. In at least one example, thepatient-specific void 110 exactly matches the void of the glenoid defect104 of the specific patient 106. In at least one example, the geometryof the glenoid defect 104 can be determined in any of a variety ofmanners, including patient imaging for example, X-ray, CT (computerizedtomography), MRI (magnetic resonance imaging), pre-operative planningtools and the like. In at least one example, patient scans can beconverted into three dimensional models to determine the threedimensional size and shape of the glenoid defect. In at least oneexample, segmentation of CT scans is used to determine the size andshape of the glenoid defect. The patient-specific punch 100 is formedfor the specific patient. In at least one example, the patient-specificpunch 100 would only match the geometry of the specific patient forwhich it was created.

In at least one example, the patient-specific punch 100 can include apatient-specific void 110 that matches specific dimensions of theglenoid defect 104, but does not exactly match the entire geometry ofthe glenoid defect 104. For example, the patient-specific void 110 canmatch a two-dimensional outline 112 of the glenoid defect 104, such thatthe patient-specific punch 100 can form a patient-specific glenoidimplant 102 that includes the dimensions of the outline 112 butcontinues those dimensions for a fixed height 114. In other examples,the patient-specific punch 100 can include a patient-specific void 110that matches different selected portions of the geometry of the glenoiddefect 104.

In some examples, the patient-specific punch 100 can be driven into animplant material to form the patient-specific glenoid implant 102. Insome examples, the implant material can comprise bone. In at least oneexample, the implant can comprise an allograft. In some examples, theimplant material can comprise an autograft. In at least one example, theimplant material can comprise a resected humeral head portion of thespecific patient 106. In some examples, the implant material cancomprise cancellous bone.

FIG. 2A is a perspective view of a patient-specific shaping block 200for shaping the patient-specific glenoid implant 102, in accordance withat least one example of the present disclosure. In some examples, thepatient-specific shaping block 200 can include a cover 202 configured tobe placed over the patient-specific shaping block 200. In at least oneexample, the box can include one or more lid features 204 configured tointeract with the cover 202 to seat, center, or secure the cover 202 onthe block 200.

In some examples, the patient-specific shaping block 200 can include ablock void 206. In at least one example, the block void 206 can includea patient-specific portion corresponding to the glenoid defect 104 ofthe specific patient 106. In at least one example, the patient-specificportion 208 can match the geometry of the glenoid defect 104. In someexamples, the block void 206 can further include a base plate portion210 corresponding to a base plate, for example, a base plate used duringshoulder surgery. In some examples, the block void 206 can include animpactor seat 212 configured to receive an impactor head duringimpaction. In some examples, the cover 202 can be configured to receivethe impactor head and can include one or more features to transfer theimpact to the patient-specific glenoid implant 102.

In some examples, the patient-specific shaping block 200 can include oneor more fastener holes 214 for receiving a fastener. In at least oneexample, the cover 202 can include one or more fastener holes 216corresponding to one or more fastener holes 214 of the patient-specificshaping block 200. In some examples, the fastener can comprise a pin, adrill bit, a wire, or the like. In at least one example, the fastenercan comprise a 3.2 mm diameter Steinman pin. In at least one example,the cover 202 can receive a 3.2 mm Steinman pin to be placed in thecenter of the glenoid post which can allow for accurate reaming andsimilarities between the Comprehensive® Reverse Shoulder System andglenoid reconstruction techniques. In at least one example, the cover202 can provide alignment for a drill or other tool. In at least oneexample, the cover 202 can be a drill guide. In at least one example,one or more tools can be cannulated, such that the one or more tools beslid over the pin for controlled alignment. In at least one example, thepatient-specific shaping block 200 can be used to shape thepatient-specific glenoid implant 102 created by the patient-specificpunch 100.

FIG. 2B is another perspective view of the patient-specific shapingblock 200 without the cover 202, in accordance with at least one exampleof the present disclosure. In the illustrated example, thepatient-specific shaping block 200 can include a lid attachment feature218. In some examples, the lid attachment feature 218 can be a pin aboutwhich the cover 202 can pivot. In some examples, the lid attachmentfeature 218 can include any of a variety of alignment features, forexample, peg, hole, tab, latch, slot, etc. In at least one example, thelid attachment feature 218 can be a press-fit feature. In at least oneexample, the lid attachment feature 218 can comprise a hinge point. Insome examples, the cover 202 can include a corresponding attachmentfeature that corresponds to the lid attachment feature 218. In at leastone example, the patient-specific shaping block 200 does not include thecover 202.

FIG. 2C is a perspective view of a spacer 220 and a spacer removal tool222, in accordance with at least one example of the present disclosure.In at least one example, the spacer 220 can match the geometry of thebase plate, such that the spacer 220 can shape the patient-specificglenoid implant 102 to fit the base plate. In at least one example, thespacer 220 can ensure the patient-specific glenoid implant 102 takes theshape needed to fill the void of the glenoid defect 104. In someexamples, the spacer 220 can include a defect feature 224 to allow spacefor the patient-specific glenoid implant 102 in the patient-specificshaping block 200. In at least one example, the defect feature 224 canbe patient-specific.

In some examples, the spacer 220 can include a removal feature 226, suchthat a removal portion 228 of the removal tool 222 can interact with theremoval feature 226 to remove the spacer 220 from the patient-specificshaping block 200. In at least one example, the removal feature 226 canallow for removal of the spacer 220 without the use of a specific spacerremoval tool 222. While in the illustrated example the removal feature226 comprises a recess that receives the removal portion 228 of theremoval tool 222, in other examples, the removal feature 226 and theremoval portion 228 can include any features that interact for removalof the spacer 220 from the patient-specific shaping block 200. In atleast one example, the spacer removal tool 222 can create a lever armwhen interacting with the spacer 220 to pop the spacer 220 out of thepatient-specific shaping block 200.

FIG. 2D is a cross-section view of the spacer 220 inserted into thepatient-specific shaping block 200 to shape the patient-specific glenoidimplant 102, in accordance with at least one example of the presentdisclosure. In the illustrated example, the patient-specific glenoidimplant 102 can extend into impactor space 230 between the impactor seat212 and a top surface 232 of the patient-specific shaping block 200. Inat least one example, an impactor can be used to apply force to thepatient-specific glenoid implant 102, such that the patient-specificglenoid implant 102 fills the patient-specific portion 208 of the blockvoid 206 to match the geometry of the glenoid defect 104 whileaccommodating the base plate. After the patient-specific glenoid implant102 has been impacted to fill the patient-specific portion 208 of theblock void 206, the spacer 220 can be removed with the spacer removaltool 222 or otherwise, and the patient-specific glenoid implant 102 canbe prepared for implantation in the glenoid defect 104 of the specificpatient 106. In at least one example, the spacer 220 can controlcritical features when impacting the patient-specific glenoid implant102 made, for example, of cancellous bone. In at least one example, thespacer 220 can have the geometry of the Comprehensive® Reverse ShoulderSystem base plate to ease the reaming process needed for implanting aComprehensive® Reverse Shoulder System base plate with thepatient-specific glenoid implant 102. In at least one example, thespacer 220 can have the geometry of the Trabecular Metal™ ReverseShoulder System base plate to ease the reaming process needed forimplanting a Trabecular Metal™ Reverse Shoulder System base plate withthe patient-specific glenoid implant 102.

FIG. 3A is a perspective view of an impactor 300 in accordance with atleast one example of the present disclosure. The impactor 300 caninclude an impactor body 302 and an impactor attachment 304. In theillustrated example, the impactor attachment 304 can comprise thepatient-specific punch 100 of FIG. 1 including the patient-specific void110. In at least one example, the impactor body 302 can include anattachment portion 306 configured to interact with one or moreattachment features 308 of the impactor attachment 304. In at least oneexample, the attachment portion 306 of the impactor body 302 can allowone or more impactor attachments 304 to be removably coupled to theimpactor body 302. In at least one example, the impactor body 302 can beused for multiple surgeries and multiple patients. In at least oneexample, some of the impactor attachments 304, such as thepatient-specific punch 100, are patient-specific and can only be usedfor the specific patient 106 with which they correspond. In this manner,when the patient-specific punch 100 is no longer needed, it can beremoved from the impactor body 302 and disposed of, but the impactorbody 302 can still be used with other impactor attachment 304.

FIG. 3B is a perspective view of another impactor attachment 304 inaccordance with at least one example of the present disclosure. In atleast one example, the impactor attachment 304 can include an impactorhead attachment 310. In some examples, the impactor head attachment 310can include one or more attachment features 308, such that the impactorhead attachment 310 can be removably coupled to the impactor body 302.In at least one example, the impactor head attachment 310 can include ageneric impactor face 312. In at least one example, the impactor headattachment 310 can be shaped and sized to fit within the impactor seat212 of the patient-specific shaping block 200. In at least one example,the impactor head attachment 310 can include one or morepatient-specific features to facilitate shaping of the patient-specificglenoid implant 102 to fill the glenoid defect 104.

FIG. 4 is a perspective view of a bone cutter 400, in accordance with atleast one example of the present disclosure. In some examples, the bonecutter 400 can include an extraction block 402 configured to receive animplant material 404. In some examples, the implant material 404 cancomprise an allograft. In at least one example, the implant material 404can comprise an autograft. In at least one example, the implant material404 can comprise a resected humeral head. In some examples, the bonecutter 400 can include one or more fastener apertures 406, eachconfigured to receive a fastener, for example a pin 408, a screw 410, orthe like. In at least one example, one or more of the fasteners 408, 410can be configured to be driven into the implant material 404.

In some examples, the bone cutter 400 can include a rotatable bladeassembly 412. In at least one example, the blade assembly 412 can becoupled to the fastener 410 driven through the extraction block 402 andthe implant material 404. In at least one example, the blade assembly412 can be coupled to the implant material 404. In at least one example,the blade assembly 412 can be coupled to the extraction block 402. Insome examples the blade assembly 412 can include one or more arcuateblades 414. In at least one example, the blade 414 can comprise anexplant knife. In some examples, a user can place the implant material404 in the extraction block 402, insert the fasteners 408, 410, andattach the blade assembly 412. In at least one example, the implantmaterial can comprise a resected humeral head, which can be placed intothe extraction block 402 cortical side first. In at least one example,after the blade assembly is attached, the blade assembly 412 can berotated to cut the implant material 404 to form a bone puck. In someexamples, the blade 414 can pivot within a range 416, for example 30degrees to allow the changes in the angle of the blade 414. In at leastone example, the pivot range 416 can facilitate entry of the blade 414into the implant material 404. In at least one example, the pivot range416 can allow the cut of the blade 414 to cater to the naturalanatomical shape of the humeral head, which can allow the surgeon tomaximize the amount of available bone, which can give the surgeon abetter chance at being able to address the defect by giving them morecancellous material to work with. In at least one example, the bladeassembly 412 can be set to a predetermined depth, such that the blade414 will only cut to the predetermined depth to create the bone puckshape needed by the surgeon. In at least one example, the bone cutter400 can create a cone-shaped bone puck.

In at least one example, the patient-specific punch 100 (FIG. 1) canimpact the bone puck to form the patient-specific glenoid implant 102.In at least one example, the patient-specific glenoid implant 102 canthen be placed in the patient-specific shaping block 200 with the spacer220 and impacted to shape the patient-specific glenoid implant 102. Insome examples, the patient-specific glenoid implant 102 will thenperfectly match the glenoid defect 104 of the specific patient 106 andcan be implanted into the glenoid defect 104 of the specific patient106. In at least one example, the patient-specific glenoid implant 102can be reamed to facilitate implantation. In at least one example, thepatient-specific implant 102 can be coupled to the base plate beforebeing implanted into the anatomy of the specific patient 106. In atleast one example, the base plate can be coupled to the patient-specificimplant 102 with a peripheral screw.

FIG. 5 is a perspective view of a patient-specific bone substituteinjector 500, in accordance with at least one example of the presentdisclosure. In at least one example, the patient-specific bonesubstitute injector 500 can include an injector 502, a nozzle 504, and apatient-specific portion 506. In at least one example, thepatient-specific portion 506 can comprise a patient-specific glenoidsleeve that can be placed over the face of the glenoid defect 104. In atleast one example, the glenoid sleeve concentrates bone substitute 508to directly fill the glenoid defect 104 through a patient-specificfeature 510. In at least one example, the glenoid sleeve constrainswhere the bone substitute can be injected such that it only fills theglenoid defect 104. In at least one example, the patient-specificportion 506 can include a vacuum seal adapter to attach to the glenoidsleeve to create a sealed lining around the glenoid 108. In at least oneexample, the patient-specific portion 506 can form a secure, semi-sealedfit with the glenoid 108. In at least one example, the patient-specificportion 506 can prevent bone substitute 508 from attaching to areaswhere it is not needed. In at least one example, the patient-specificportion 506 can be a cap coupled to the nozzle 506 with apatient-specific feature 510 to direct the bone substitute 508 into theglenoid defect 104. In at least one example, the patient-specificportion 506 can include one or more attachment features 512 to fit thepatient-specific portion 506 over the glenoid 108 of the specificpatient 106. In some examples, the patient-specific portion 506 can befit over the glenoid 108 of the specific patient, and the injector 502can inject bone substitute 508 to fill the glenoid defect 104, which canset to form the patient-specific implant 102 within the glenoid defect104 of the specific patient 106. In at least one example, thepatient-specific portion 506 can then be disposed of, while the injector502 can be reused for subsequent surgeries or subsequent patients. Forexample, a new patient-specific portion (corresponding to a glenoiddefect of a new patient) can be coupled to the injector 502 and theprocess can be repeated.

In at least one example, the patient-specific bone substitute injector500 can allow for a patient-specific glenoid implant 102 to be createdwith less equipment. In some examples, before or after the bonesubstitute 508 has cured within the glenoid defect 104, thepatient-specific glenoid implant 102 can be resurfaced as needed, forexample, to create a flat surface.

FIG. 6 is a perspective view of an injector 600 and a patient-specificmold 602, in accordance with at least one example of the presentdisclosure. In at least one example, the patient-specific mold 602 caninclude a patient-specific void 604 corresponding to the glenoid defect104 of the specific patient 106. In at least one example, thepatient-specific void 604 can match the glenoid defect 104. In someexamples, the patient-specific mold 602 can include multiple portions606, 608 coupled together via one or more locking features 610. In atleast one example, the patient-specific mold 602 can be a single unitarypiece. In some examples, the patient-specific mold can include anopening 612 for receiving bone substitute 614 from the injector 600 tofill the patient-specific void 604. In at least one example, after thepatient-specific void 604 is filled with the bone substitute, and thebone substitute has been allowed to cure, the one or more lockingfeatures 610 of the patient-specific mold 602 can be disengaged, and thepatient-specific glenoid implant 102 can be removed from thepatient-specific mold 602. In at least one example, the patient-specificglenoid implant 102 can then be implanted into the glenoid defect 104 ofthe specific patient 106.

FIG. 7 is a perspective view of the patient-specific glenoid implant 102implanted in the anatomy of the specific patient 106 to repair theglenoid defect 104 of the specific patient, in accordance with at leastone example of the present disclosure. In some examples, thepatient-specific glenoid implant 102 can be formed using any one or moreof the apparatus, systems and methods described with reference to FIGS.1-6. In at least one example, the patient-specific glenoid implant 102can be attached to a base plate or other device before implantation intothe glenoid defect 104. In some examples, the patient-specific glenoidimplant can be formed of bone, for example, cancellous bone from ahumeral head resection of the specific patient 106, or other bone. Insome examples, the patient-specific glenoid implant can be formed ofbone substitute, for example, Equivabone®, Gamma-BSM, CarriGen®,Beta-BSM, or the like. In at least on example, the patient-specificglenoid implant can be formed of osteoconductive, osteoinductiveself-setting bone void filler. In at least one example, thepatient-specific glenoid implant 102 can be oversized (e.g., byenlarging the geometry of the patient-specific devices) to facilitateinterdigitating of the patient-specific glenoid implant 102 with thesurrounding bone. In at least one example, the patient-specific glenoidimplant can be provided with additional material to improve initialfixation. In at least one example, the implant material of thepatient-specific glenoid implant 102 is both osteoconductive andosteoinductive.

In at least one example, the apparatus, systems and methods of FIGS. 1-7can allow for a surgeon to precisely match a specific patient's anatomyevery time, without needing to resect bone from the scapular or thelatarjet. In at least one example, the apparatus, systems and methods ofFIGS. 1-7 can allow for a surgeon to place a patient-specific glenoidimplant without extreme difficulty. In at least one example, theapparatus, systems and methods of FIGS. 1-7 can be utilized as atwo-stage process within VRS (Vault Reconstruction System), TrabecularMetal™ Reverse Shoulder System, Comprehensive® Reverse Shoulder System,PMI® (Patient Matched Implant), or other shoulder system cases. Forexample, the system can first be used to partially fill the glenoiddefect (which can be allowed to harden or potentially to heal the bonefirst), then a subsequent patient-specific implant can be used to matchthe new shape of the glenoid (with the glenoid defect already filled).In at least one example, the allograft injection method can be followedup by anatomical glenoid systems after the bone has healed. In at leastone example, the apparatus, systems and methods of FIGS. 1-7 can allowfor a reduction in surgical time and better fixation, screw purchase,geometry, and overall formality within the specific patient.

In the foregoing Detailed Description, it can be seen that variousfeatures are grouped together in a single example for the purpose ofstreamlining the disclosure. This method of disclosure is not to beinterpreted as reflecting an intention that the claimed examples requiremore features than are expressly recited in each claim. Rather, as thefollowing claims reflect, inventive subject matter lies in less than allfeatures of a single disclosed example. Thus the following claims arehereby incorporated into the Detailed Description, with each claimstanding on its own as a separate example.

Note that not all of the activities or elements described above in thegeneral description are required, that a portion of a specific activityor device may not be required, and that one or more further activitiesmay be performed, or elements included, in addition to those described.Still further, the order in which activities are listed are notnecessarily the order in which they are performed. Also, the conceptshave been described with reference to specific examples. However, one ofordinary skill in the art appreciates that various modifications andchanges can be made without departing from the scope of the presentdisclosure as set forth in the claims below. Accordingly, thespecification and figures are to be regarded in an illustrative ratherthan a restrictive sense, and all such modifications are intended to beincluded within the scope of the present disclosure.

Benefits, other advantages, and solutions to problems have beendescribed above with regard to specific examples. However, the benefits,advantages, solutions to problems, and any feature(s) that may cause anybenefit, advantage, or solution to occur or become more pronounced arenot to be construed as a critical, required, or essential feature of anyor all the claims. Moreover, the particular examples disclosed above areillustrative only, as the disclosed subject matter may be modified andpracticed in different but equivalent manners apparent to those skilledin the art having the benefit of the teachings herein. No limitationsare intended to the details of construction or design herein shown,other than as described in the claims below. It is therefore evidentthat the particular examples disclosed above may be altered or modifiedand all such variations are considered within the scope of the disclosedsubject matter. Accordingly, the protection sought herein is as setforth in the claims below.

What is claimed is:
 1. A system for repairing a glenoid defect of aspecific patient, the system comprising: an impactor body; and apatient-specific punch coupled to the impactor body, thepatient-specific punch including a patient-specific void correspondingto the glenoid defect; wherein the impactor body is configured to drivethe patient-specific punch into an implant material to form apatient-specific glenoid implant.
 2. The system of claim 1, wherein thepatient-specific punch is removably coupled to the impactor body.
 3. Thesystem of claim 1, wherein the implant material comprises a bone puckformed from a resected portion of a humeral head.
 4. They system ofclaim 1, wherein the patient-specific glenoid implant is configured tobe coupled to a base plate that is configured to be coupled to theglenoid.
 5. The system of claim 4, further comprising: apatient-specific shaping block configured to receive thepatient-specific glenoid implant in a shaping void; and a spacerconfigured for placement in the patient-specific shaping block, thespacer having a geometry corresponding to the base plate; wherein theshaping void is configured to match the glenoid defect; wherein thepatient-specific glenoid implant is configured to be impacted such thatthe shaping void and the spacer shape the patient-specific glenoidimplant to repair the glenoid defect.
 6. The system of claim 5, furthercomprising: an impactor head configured to be removably coupled to theimpactor body.
 7. The system of claim 5, wherein the patient-specificshaping block further includes a cover, the cover configured to receivea guide pin.
 8. The system of claim 5, further comprising a base platereamer configured to ream the patient-specific glenoid implant to matchfeatures of the base plate.
 9. The system of claim 1, wherein thepatient-specific punch includes knifed edges.
 10. A system for repairinga glenoid defect of a specific patient, the system comprising: apatient-specific punch including a patient-specific void correspondingto the glenoid defect, the patient-specific punch configured to form apatient-specific glenoid implant; and a patient-specific shaping blockconfigured to receive the patient-specific glenoid implant in a shapingvoid that matches the glenoid defect; wherein the patient-specificglenoid implant is configured to be impacted such that the shaping voidshapes the patient-specific glenoid implant to fill the glenoid defect.11. The system of claim 10, further comprising: a base plate configuredto be coupled to the patient-specific glenoid implant for implantationin the specific patient.
 12. The system of claim 11, further comprising:a spacer configured to be inserted into the patient-specific shapingblock, the spacer having a geometry corresponding to the base plate. 13.The system of claim 10, further comprising: a bone cutter configured toform a bone puck, wherein the patient-specific punch is configured toimpact the bone puck to form the patient-specific glenoid implant. 14.The system of claim 13, wherein the bone cutter comprises: an extractionblock configured to receive a humeral head resection; a fastenerconfigured to extend through the humeral head resection; and a rotatableblade assembly configured to be received by, and rotate around, thefastener to cut the humeral head resection to form the bone puck. 15.The system of claim 10, further comprising: an impactor body comprisingan attachment portion configured to be removably coupled to one or moreattachments, wherein the patient-specific punch is configured to beremovably coupled to the attachment portion of the impactor body. 16.The system of claim 15, further comprising: an impactor head attachmentconfigured to be removably coupled to the attachment portion of theimpactor body.
 17. A method for repairing a glenoid defect of a specificpatient, the method comprising: driving a patient-specific punch into animplant material to create a patient-specific glenoid implant, whereinthe patient-specific punch includes a patient-specific voidcorresponding to the glenoid defect; placing the patient-specificglenoid implant in a patient-specific shaping block including a shapingvoid that matches the glenoid defect; and impacting the patient-specificglenoid implant, such that the patient-specific shaping block shapes thepatient-specific implant to fill the glenoid defect.
 18. The method ofclaim 17, further comprising: forming the bone puck from a resectedportion of a humeral head.
 19. The method of claim 17, furthercomprising: reaming the patient-specific implant to accommodate a baseplate.
 20. The method of claim 19, further comprising: coupling thepatient-specific glenoid implant to the base plate that is configured tobe coupled to the glenoid.